लिनक्स/linux-0.01.tar/kernel/hd.c
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#include <linux/config.h> #include <linux/sched.h> #include <linux/fs.h> #include <linux/kernel.h> #include <linux/hdreg.h> #include <asm/system.h> #include <asm/io.h> #include <asm/segment.h> /* * This code handles all hd-interrupts, and read/write requests to * the hard-disk. It is relatively straigthforward (not obvious maybe, * but interrupts never are), while still being efficient, and never * disabling interrupts (except to overcome possible race-condition). * The elevator block-seek algorithm doesn't need to disable interrupts * due to clever programming. */ /* Max read/write errors/sector */ #define MAX_ERRORS 5 #define MAX_HD 2 #define NR_REQUEST 32 /* * This struct defines the HD's and their types. * Currently defined for CP3044's, ie a modified * type 17. */ static struct hd_i_struct{ int head,sect,cyl,wpcom,lzone,ctl; } hd_info[]= { HD_TYPE }; #define NR_HD ((sizeof (hd_info))/(sizeof (struct hd_i_struct))) static struct hd_struct { long start_sect; long nr_sects; } hd[5*MAX_HD]={{0,0},}; static struct hd_request { int hd; /* -1 if no request */ int nsector; int sector; int head; int cyl; int cmd; int errors; struct buffer_head * bh; struct hd_request * next; } request[NR_REQUEST]; #define IN_ORDER(s1,s2) \ ((s1)->hd<(s2)->hd || (s1)->hd==(s2)->hd && \ ((s1)->cyl<(s2)->cyl || (s1)->cyl==(s2)->cyl && \ ((s1)->head<(s2)->head || (s1)->head==(s2)->head && \ ((s1)->sector<(s2)->sector)))) static struct hd_request * this_request = NULL; static int sorting=0; static void do_request(void); static void reset_controller(void); static void rw_abs_hd(int rw,unsigned int nr,unsigned int sec,unsigned int head, unsigned int cyl,struct buffer_head * bh); void hd_init(void); #define port_read(port,buf,nr) \ __asm__("cld;rep;insw"::"d" (port),"D" (buf),"c" (nr):"cx","di") #define port_write(port,buf,nr) \ __asm__("cld;rep;outsw"::"d" (port),"S" (buf),"c" (nr):"cx","si") extern void hd_interrupt(void); static struct task_struct * wait_for_request=NULL; static inline void lock_buffer(struct buffer_head * bh) { if (bh->b_lock) printk("hd.c: buffer multiply locked\n"); bh->b_lock=1; } static inline void unlock_buffer(struct buffer_head * bh) { if (!bh->b_lock) printk("hd.c: free buffer being unlocked\n"); bh->b_lock=0; wake_up(&bh->b_wait); } static inline void wait_on_buffer(struct buffer_head * bh) { cli(); while (bh->b_lock) sleep_on(&bh->b_wait); sti(); } void rw_hd(int rw, struct buffer_head * bh) { unsigned int block,dev; unsigned int sec,head,cyl; block = bh->b_blocknr << 1; dev = MINOR(bh->b_dev); if (dev >= 5*NR_HD || block+2 > hd[dev].nr_sects) return; block += hd[dev].start_sect; dev /= 5; __asm__("divl %4":"=a" (block),"=d" (sec):"0" (block),"1" (0), "r" (hd_info[dev].sect)); __asm__("divl %4":"=a" (cyl),"=d" (head):"0" (block),"1" (0), "r" (hd_info[dev].head)); rw_abs_hd(rw,dev,sec+1,head,cyl,bh); } /* This may be used only once, enforced by 'static int callable' */ int sys_setup(void) { static int callable = 1; int i,drive; struct partition *p; if (!callable) return -1; callable = 0; for (drive=0 ; drive<NR_HD ; drive++) { rw_abs_hd(READ,drive,1,0,0,(struct buffer_head *) start_buffer); if (!start_buffer->b_uptodate) { printk("Unable to read partition table of drive %d\n\r", drive); panic(""); } if (start_buffer->b_data[510] != 0x55 || (unsigned char) start_buffer->b_data[511] != 0xAA) { printk("Bad partition table on drive %d\n\r",drive); panic(""); } p = 0x1BE + (void *)start_buffer->b_data; for (i=1;i<5;i++,p++) { hd[i+5*drive].start_sect = p->start_sect; hd[i+5*drive].nr_sects = p->nr_sects; } } printk("Partition table%s ok.\n\r",(NR_HD>1)?"s":""); mount_root(); return (0); } /* * This is the pointer to a routine to be executed at every hd-interrupt. * Interesting way of doing things, but should be rather practical. */ void (*do_hd)(void) = NULL; static int controller_ready(void) { int retries=1000; while (--retries && (inb(HD_STATUS)&0xc0)!=0x40); return (retries); } static int win_result(void) { int i=inb(HD_STATUS); if ((i & (BUSY_STAT | READY_STAT | WRERR_STAT | SEEK_STAT | ERR_STAT)) == (READY_STAT | SEEK_STAT)) return(0); /* ok */ if (i&1) i=inb(HD_ERROR); return (1); } static void hd_out(unsigned int drive,unsigned int nsect,unsigned int sect, unsigned int head,unsigned int cyl,unsigned int cmd, void (*intr_addr)(void)) { register int port asm("dx"); if (drive>1 || head>15) panic("Trying to write bad sector"); if (!controller_ready()) panic("HD controller not ready"); do_hd = intr_addr; outb(_CTL,HD_CMD); port=HD_DATA; outb_p(_WPCOM,++port); outb_p(nsect,++port); outb_p(sect,++port); outb_p(cyl,++port); outb_p(cyl>>8,++port); outb_p(0xA0|(drive<<4)|head,++port); outb(cmd,++port); } static int drive_busy(void) { unsigned int i; for (i = 0; i < 100000; i++) if (READY_STAT == (inb(HD_STATUS) & (BUSY_STAT | READY_STAT))) break; i = inb(HD_STATUS); i &= BUSY_STAT | READY_STAT | SEEK_STAT; if (i == READY_STAT | SEEK_STAT) return(0); printk("HD controller times out\n\r"); return(1); } static void reset_controller(void) { int i; outb(4,HD_CMD); for(i = 0; i < 1000; i++) nop(); outb(0,HD_CMD); for(i = 0; i < 10000 && drive_busy(); i++) /* nothing */; if (drive_busy()) printk("HD-controller still busy\n\r"); if((i = inb(ERR_STAT)) != 1) printk("HD-controller reset failed: %02x\n\r",i); } static void reset_hd(int nr) { reset_controller(); hd_out(nr,_SECT,_SECT,_HEAD-1,_CYL,WIN_SPECIFY,&do_request); } void unexpected_hd_interrupt(void) { panic("Unexpected HD interrupt\n\r"); } static void bad_rw_intr(void) { int i = this_request->hd; if (this_request->errors++ >= MAX_ERRORS) { this_request->bh->b_uptodate = 0; unlock_buffer(this_request->bh); wake_up(&wait_for_request); this_request->hd = -1; this_request=this_request->next; } reset_hd(i); } static void read_intr(void) { if (win_result()) { bad_rw_intr(); return; } port_read(HD_DATA,this_request->bh->b_data+ 512*(this_request->nsector&1),256); this_request->errors = 0; if (--this_request->nsector) return; this_request->bh->b_uptodate = 1; this_request->bh->b_dirt = 0; wake_up(&wait_for_request); unlock_buffer(this_request->bh); this_request->hd = -1; this_request=this_request->next; do_request(); } static void write_intr(void) { if (win_result()) { bad_rw_intr(); return; } if (--this_request->nsector) { port_write(HD_DATA,this_request->bh->b_data+512,256); return; } this_request->bh->b_uptodate = 1; this_request->bh->b_dirt = 0; wake_up(&wait_for_request); unlock_buffer(this_request->bh); this_request->hd = -1; this_request=this_request->next; do_request(); } static void do_request(void) { int i,r; if (sorting) return; if (!this_request) { do_hd=NULL; return; } if (this_request->cmd == WIN_WRITE) { hd_out(this_request->hd,this_request->nsector,this_request-> sector,this_request->head,this_request->cyl, this_request->cmd,&write_intr); for(i=0 ; i<3000 && !(r=inb_p(HD_STATUS)&DRQ_STAT) ; i++) /* nothing */ ; if (!r) { reset_hd(this_request->hd); return; } port_write(HD_DATA,this_request->bh->b_data+ 512*(this_request->nsector&1),256); } else if (this_request->cmd == WIN_READ) { hd_out(this_request->hd,this_request->nsector,this_request-> sector,this_request->head,this_request->cyl, this_request->cmd,&read_intr); } else panic("unknown hd-command"); } /* * add-request adds a request to the linked list. * It sets the 'sorting'-variable when doing something * that interrupts shouldn't touch. */ static void add_request(struct hd_request * req) { struct hd_request * tmp; if (req->nsector != 2) panic("nsector!=2 not implemented"); /* * Not to mess up the linked lists, we never touch the two first * entries (not this_request, as it is used by current interrups, * and not this_request->next, as it can be assigned to this_request). * This is not too high a price to pay for the ability of not * disabling interrupts. */ sorting=1; if (!(tmp=this_request)) this_request=req; else { if (!(tmp->next)) tmp->next=req; else { tmp=tmp->next; for ( ; tmp->next ; tmp=tmp->next) if ((IN_ORDER(tmp,req) || !IN_ORDER(tmp,tmp->next)) && IN_ORDER(req,tmp->next)) break; req->next=tmp->next; tmp->next=req; } } sorting=0; /* * NOTE! As a result of sorting, the interrupts may have died down, * as they aren't redone due to locking with sorting=1. They might * also never have started, if this is the first request in the queue, * so we restart them if necessary. */ if (!do_hd) do_request(); } void rw_abs_hd(int rw,unsigned int nr,unsigned int sec,unsigned int head, unsigned int cyl,struct buffer_head * bh) { struct hd_request * req; if (rw!=READ && rw!=WRITE) panic("Bad hd command, must be R/W"); lock_buffer(bh); repeat: for (req=0+request ; req<NR_REQUEST+request ; req++) if (req->hd<0) break; if (req==NR_REQUEST+request) { sleep_on(&wait_for_request); goto repeat; } req->hd=nr; req->nsector=2; req->sector=sec; req->head=head; req->cyl=cyl; req->cmd = ((rw==READ)?WIN_READ:WIN_WRITE); req->bh=bh; req->errors=0; req->next=NULL; add_request(req); wait_on_buffer(bh); } void hd_init(void) { int i; for (i=0 ; i<NR_REQUEST ; i++) { request[i].hd = -1; request[i].next = NULL; } for (i=0 ; i<NR_HD ; i++) { hd[i*5].start_sect = 0; hd[i*5].nr_sects = hd_info[i].head* hd_info[i].sect*hd_info[i].cyl; } set_trap_gate(0x2E,&hd_interrupt); outb_p(inb_p(0x21)&0xfb,0x21); outb(inb_p(0xA1)&0xbf,0xA1); }